The Infrared Atmospheric Sounding Interferometer (IASI), on-board the EUMETSAT Polar System Metop satellite, is developed by CNES in the framework of a co-operation agreement with EUMETSAT. IASI enables, amongst other, infrared soundings of temperature, moisture and retrievals of surface parameters. However in the numerical weather prediction context, these observations are not as intensively used over land as they are over sea because of larger uncertainties about land emissivity and land surface temperature (LST). These uncertainties have an impact on the quality of radiative transfer simulation and hinder the use of these measurements in numerical weather prediction models. Only channels that are not sensitive to the surface are currently assimilated in operations, which limits the potential of sounding instruments to the highest atmospheric layers. This PhD aims to improve the description of land surface parameters in the ARPEGE global model of Météo-France to assimilate IASI data over land. First of all, we tried to improve the surface modelling (surface emissivity and LST) over land in the ARPEGE model. To this end, two emissivity atlases were integrated in this model. The first one is the emissivity climatology computed from the IASI Level-2 products from EUMETSAT and the second one is the global high spectral resolution infrared land surface emissivity database (called UWIREMIS) developed by the Space Science and Engineering Center at University of Wisconsin. Hence, the LST was retrieved from IASI surface channels using these atlases as input parameters in the radiative transfer model. These LSTs were compared to land LST products: the MODIS (Moderate-Resolution Imaging Spectroradiometer) products from the NASA and the IASI Level-2 products from EUMETSAT. These comparisons enabled us to choose the IASI channel combination that provided the best LST estimates. The use of a realistic surface modelling contributed to improve the quality of radiative transfer simulations for surface sensitive channels. Then, surface sensitive IASI radiances were assimilated over land in ARPEGE in clear sky conditions using the surface parameters as previously defined. The impact on analysis and forecast quality was studied. The use of good estimates of surface emissivity and LST significantly increased the number of assimilated observations. The main improvements are for geopotential and temperature forecasts for pressure levels lower than 400 hPa (except in the tropics and in the stratosphere). Finally, from a climatological point of view and within the more specific framework of the Concordiasi campaign, we assessed and validated the use of IASI data in Antarctica. The temperature and humidity retrieved in this particular study proved of better quality than the model profiles, as assessed against the sonde measurements. The improvement is particularly striking for surface temperature. In this framework, the LST retrieved in this PhD were compared with in situ measurements at Concordia and at South Pole station. These estimates are of a great accuracy at Concordia.

@Phdthesis{Vincensini2013,
Title = {Contribution de IASI à l’estimation des paramètres des surfaces continentales pour la prévision numérique du temps. IASI contribution to land surface parameter retrievals for numerical weather prediction},
Author = {Vincensini, A.},
Beginningdate = {2010},
Country = {France},
Enddate = {2013.12.19},
Laboratory = {CNRM-GAME CNRS Météo-France},
Location = {Toulouse},
School = {Université de Toulouse},
Supervisors = {N. Fourrié, F. Rabier},
Supervisorsaffiliations = {CNRM-GAME CNRS Météo-France},
Year = {2013},
Address = {nadia.fourrie@meteo.fr;},
Jointdegree = {No},
Abstract = {The Infrared Atmospheric Sounding Interferometer (IASI), on-board the EUMETSAT Polar System Metop satellite, is developed by CNES in the framework of a co-operation agreement with EUMETSAT. IASI enables, amongst other, infrared soundings of temperature, moisture and retrievals of surface parameters. However in the numerical weather prediction context, these observations are not as intensively used over land as they are over sea because of larger uncertainties about land emissivity and land surface temperature (LST). These uncertainties have an impact on the quality of radiative transfer simulation and hinder the use of these measurements in numerical weather prediction models. Only channels that are not sensitive to the surface are currently assimilated in operations, which limits the potential of sounding instruments to the highest atmospheric layers. This PhD aims to improve the description of land surface parameters in the ARPEGE global model of Météo-France to assimilate IASI data over land. First of all, we tried to improve the surface modelling (surface emissivity and LST) over land in the ARPEGE model. To this end, two emissivity atlases were integrated in this model. The first one is the emissivity climatology computed from the IASI Level-2 products from EUMETSAT and the second one is the global high spectral resolution infrared land surface emissivity database (called UWIREMIS) developed by the Space Science and Engineering Center at University of Wisconsin. Hence, the LST was retrieved from IASI surface channels using these atlases as input parameters in the radiative transfer model. These LSTs were compared to land LST products: the MODIS (Moderate-Resolution Imaging Spectroradiometer) products from the NASA and the IASI Level-2 products from EUMETSAT. These comparisons enabled us to choose the IASI channel combination that provided the best LST estimates. The use of a realistic surface modelling contributed to improve the quality of radiative transfer simulations for surface sensitive channels. Then, surface sensitive IASI radiances were assimilated over land in ARPEGE in clear sky conditions using the surface parameters as previously defined. The impact on analysis and forecast quality was studied. The use of good estimates of surface emissivity and LST significantly increased the number of assimilated observations. The main improvements are for geopotential and temperature forecasts for pressure levels lower than 400~hPa (except in the tropics and in the stratosphere). Finally, from a climatological point of view and within the more specific framework of the Concordiasi campaign, we assessed and validated the use of IASI data in Antarctica. The temperature and humidity retrieved in this particular study proved of better quality than the model profiles, as assessed against the sonde measurements. The improvement is particularly striking for surface temperature. In this framework, the LST retrieved in this PhD were compared with in situ measurements at Concordia and at South Pole station. These estimates are of a great accuracy at Concordia.},
Completeentry = {No},
Owner = {hymexw},
Timestamp = {2016.01.08},
Url = {http://ethesis.inp-toulouse.fr/archive/00002600/}
}